non-biopsy diagnosis of cardiac transthyretin amyloidosis diagnosi… · non-biopsy diagnosis of...
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Non-biopsy diagnosis of cardiac transthyretin amyloidosis
Short Title: Gillmore, Diagnosis of cardiac ATTR amyloidosis
Julian D. Gillmore, MD, PhD1, Mathew S. Maurer, MD2, Rodney H. Falk, MD3, Giampaolo Merlini,
MD4, Thibaud Damy, MD5, Angela Dispenzieri, MD6, Ashutosh D. Wechalekar, MD, DM1, John L.
Berk, MD7, Candida C. Quarta, MD, PhD1, Martha Grogan, MD6, Helen J. Lachmann, MD1, Sabahat
Bokhari, MD2, Adam Castano, MD2, Sharmila Dorbala, MD, MPH3, Geoff B. Johnson, MD, PhD6,
Andor W.J.M. Glaudemans, MD, PhD8, Tamer Rezk, BSc1, Marianna Fontana, MD1, Giovanni
Palladini, MD, PhD4, Paolo Milani, MD4, Pierluigi L. Guidalotti, MD9, Katarina Flatman1, Thirusha
Lane, MSc1, Frederick W. Vonberg, MBBS1, Carol J. Whelan, MD1, James C. Moon, MD10,
Frederick L. Ruberg, MD7, Edward J. Miller, MD, PhD11, David F. Hutt, BApSc1, Bouke P.
Hazenberg, MD, PhD8, Claudio Rapezzi, MD9, Philip N. Hawkins, PhD, FMedSci1
1National Amyloidosis Centre, Division of Medicine, University College London, UK 2Clinical Cardiovascular Research Laboratory for the Elderly, Columbia University Medical Center, New York,
USA 3Department of Cardiology and Department of Radiology, Brigham and Women’s Hospital and Harvard
Medical School, USA 4Amyloidosis Research and Treatment Center, Foundation “Istituto di Ricovero e Cura a Carattere Scientifico
(IRCCS) Policlinico San Matteo and Department of Molecular Medicine University of Pavia, Italy 5Department of Cardiology, University Hospital Henri Mondor, Amyloidosis Mondor Network, France 6Division of Hematology, Division of Cardiovascular Diseases, and Department of Radiology, Division of
Nuclear Medicine, Department of Medicine, Mayo Clinic, USA 7Amyloidosis Center, Boston University School of Medicine and Boston Medical Center, USA 8Departments of Nuclear Medicine and Molecular Imaging (AG) and Rheumatology and Clinical Immunology
(BH), University of Groningen, University Medical Center Groningen, Groningen, The Netherlands 9Department of Nuclear Medicine, S. Orsola-Malpighi Hospital, and Cardiology Unit, Department of
Experimental, Diagnostic and Specialty Medicine, Alma Mater-University of Bologna, Bologna, Italy 10Barts Heart Centre, Institute of Cardiovascular Science, University College London, UK 11Yale University School of Medicine, Section of Cardiovascular Medicine, New Haven, CT, USA
Correspondence to: Julian Gillmore, National Amyloidosis Centre, Division of Medicine,
UCL, Rowland Hill Street, London NW1 2PF
Fax: 020 7433 2844 Tel: 020 7433 2816 E-mail: [email protected]
Total word Count: 6370
Subject codes: 16, 31, 32, 110,
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Abstract
Background
Cardiac transthyretin (ATTR) amyloidosis is a progressive and fatal cardiomyopathy for
which several promising therapies are in development. The diagnosis is frequently delayed
or missed due to limited specificity of echocardiography and the traditional requirement for
histologic confirmation. It has long been recognised that technetium labelled bone
scintigraphy tracers can localise to myocardial amyloid deposits and use of this imaging
modality for diagnosis of cardiac ATTR amyloidosis has lately been revisited. We conducted
a multicentre study to ascertain the diagnostic value of bone scintigraphy in this disease.
Methods and Results
Results of bone scintigraphy and biochemical investigations were analysed from 1217
patients with suspected cardiac amyloidosis referred for evaluation in specialist centers.
Among 857 patients with histologically proven amyloid (374 with endomyocardial biopsies),
and 360 patients subsequently confirmed to have non-amyloid cardiomyopathies, myocardial
radiotracer uptake on bone scintigraphy was >99% sensitive and 86% specific for cardiac
ATTR amyloid, with ‘false positives’ almost exclusively from uptake in patients with cardiac
AL amyloidosis. Importantly, the combined findings of grade 2 or 3 myocardial radiotracer
uptake on bone scintigraphy and absence of a monoclonal protein in serum or urine had a
specificity and positive predictive value for cardiac ATTR amyloidosis of 100% (PPV CI
98.0-100).
Conclusions
Bone scintigraphy enables the diagnosis of cardiac ATTR amyloidosis to be made reliably
without need for histology in patients who do not have a monoclonal gammopathy. We
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propose non-invasive diagnostic criteria for cardiac ATTR amyloidosis that are applicable to
the majority of patients with this disease.
Key Words: amyloid, cardiomyopathy, genetics, hypertrophy, transthyretin,
99m technetium, scintigraphy
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Introduction
Cardiac amyloidosis is a rare form of restrictive cardiomyopathy which is often challenging
to diagnose and is almost always associated with a poor prognosis. The causative amyloid
fibril deposits are of monoclonal light chain (AL)1 or transthyretin (ATTR)2-4 types in the
vast majority of cases. ATTR amyloidosis may be acquired, associated with wild-type
transthyretin (previously known as senile systemic amyloidosis), or hereditary, associated
with variants in the transthyretin gene. Clinical features are varied, and whilst heart failure
symptoms predominate, suspicion of cardiac amyloidosis can also be prompted by syncope,
arrhythmias or unexplained left ventricular (LV) wall thickening on echocardiography.
Diagnosis of amyloidosis is usually obtained through biopsy of a clinically affected organ,
with Congo red histology demonstrating pathognomonic green birefringence. However,
when amyloidosis is suspected clinically, biopsy of subcutaneous fat, salivary gland or
rectum yields the diagnosis in 50-80 percent of patients with AL amyloidosis.5 A much
lower yield in patients with ATTR amyloidosis frequently results in a requirement for
endomyocardial biopsy (EMB) to confirm the diagnosis.6 EMB is associated with a risk of
complications, including myocardial perforation and tamponade which may be fatal, and
requires expertise that can introduce diagnostic delay.7
Autopsy studies have shown the presence of cardiac ATTR amyloid deposits in up to
25% of individuals over 80 years of age, although in many of these hearts the amount of
amyloid was small.8 Nevertheless, among patients with heart failure and preserved ejection
fraction (HFpEF), post-mortem examination indicates that cardiac amyloid deposition is
commoner than in an age-matched autopsy group without heart failure. The majority of
patients with cardiac amyloid on post-mortem in these studies had not had amyloidosis
diagnosed during life.9 Echocardiography, whilst a valuable and widely accessible tool for
investigating heart failure, is neither sensitive nor specific for cardiac amyloidosis.10 Typical
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findings on echocardiography include thickening of ventricular walls, restrictive filling,
abnormal left and right ventricular longitudinal strain and atrial septal thickening.11 Cardiac
magnetic resonance imaging (CMR) has much greater diagnostic value in cardiac
amyloidosis but false positive and false negative CMRs are not infrequent.12 Typical findings
include restrictive morphology, abnormal gadolinium kinetics and extracellular volume
expansion on T1 mapping.11 Furthermore, CMR is costly and only available in specialist
centers, is contraindicated in a substantial proportion of patients, and cannot reliably
distinguish different types of amyloid.13, 14 To date, definitive diagnosis of cardiac amyloid
requires histologic confirmation and typing of amyloid, recognizing issues of sampling error
and disease expertise needed for proper histologic interpretation.15 All of these factors
frequently contribute to delay in diagnosis, which is critical given the poor prognosis of
cardiac ATTR and AL amyloidosis and the increasing availability of therapies for both
diseases.4, 16, 17 Thus, there is a major unmet need to diagnose and characterise cardiac
amyloidosis at the earliest opportunity, noting that cardiac ATTR amyloidosis in particular is
probably much underdiagnosed and fast becoming a treatable cause of heart failure.18, 19
Radionuclide ‘bone’ scintigraphy with technetium labelled bisphosphonates has long
been anecdotally reported to localize to cardiac amyloid deposits, although the molecular
basis for this remains unknown.20 Recent systematic evaluation of bone scintigraphy
suggests that 99mTc-labeled 3,3-diphosphono-1,2-propanodicarboxylic acid (DPD), 99mTc-
labeled pyrophosphate (PYP) and 99mTc-labeled-hydroxymethylene diphosphonate (HMDP)
may be remarkably sensitive and specific for imaging cardiac ATTR amyloid and may
reliably distinguish other causes of cardiomyopathy that mimic amyloid such as hypertrophic
cardiomyopathy.21-25 Indeed, radionuclide ‘bone’ scintigraphy may identify cardiac ATTR
amyloid deposits early in the course of the disease, sometimes before development of
abnormalities on echocardiography or CMR,26, 27 and has been used to diagnose ATTR
6
amyloidosis among patients with HFpEF.28 Cardiac localization of radiotracer does occur in
a small proportion of patients with AL amyloidosis, and although usually low grade, it can
confound distinguishing between cardiac ATTR and AL types of amyloid.24
In October 2014, we established a collaboration of clinicians and scientists from
internationally renowned centers with expertise in clinical amyloidosis to determine whether
radionuclide ‘bone’ scintigraphy in conjunction with other imaging methods and non-
invasive laboratory investigations might enable diagnosis of cardiac ATTR amyloidosis
without need for confirmatory biopsy. Our findings presented here form the basis for a
proposed diagnostic algorithm for patients with suspected cardiac amyloidosis in which non-
biopsy diagnosis of ATTR amyloidosis can be achieved in the majority of cases.
Methods
Patients
The subjects comprised patients with suspected or histologically proven amyloidosis who had
been referred for evaluation to the following specialist amyloidosis centers in Europe and the
US: UK National Amyloidosis Centre; Amyloidosis Research and Treatment Center, Pavia
and University of Bologna in Italy; Amyloidosis Mondor Network in France; University
Medical Center, Groningen in The Netherlands; Columbia University Medical Center,
Brigham and Women’s Hospital Cardiac Amyloidosis Program, Boston, MA, Mayo Clinic,
Rochester, MN, and Amyloidosis Center, Boston University in the USA. All patients with
suspected or proven cardiac ATTR amyloidosis underwent diagnostic investigations
including bone scintigraphy, immunofixation electrophoresis (IFE) of serum and urine and
serum free light chain assay. All patients underwent echocardiography in their respective
specialist amyloidosis center; previous CMR images were reviewed, and new CMRs were
performed in patients according to local clinical practice. Final diagnosis was based on the
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results of these tests accompanied by histologic and genetic findings. A minority of the
subjects had been included in small prior published series from the individual centers. The
study received ethical approval.
Echocardiography and Cardiac Magnetic Resonance imaging at Specialist Center
Detailed echocardiography was performed at the specialist amyloid centers and included an
extensive analysis of left and right ventricular wall thickness, LV function including global
and regional longitudinal strain and atrial parameters. Diastolic function was analysed in
detail by tissue doppler imaging. Features that were characteristic of amyloid were defined
as the combined findings of thickened LV walls, impaired global strain with relative sparing
of the apical region in comparison to the base of the heart, and abnormal diastolic physiology.
CMRs were performed at the specialist amyloid centers as previously described.12, 13
Features that were characteristic of amyloid were defined as presence of diffuse
subendocardial or transmural late gadolinium enhancement coupled with abnormal
myocardial and blood-pool gadolinium kinetics.
Bisphosphonate (99mTc-DPD/99mTc-PYP/99mTc-HMDP) Scintigraphy
Patients were scanned after intravenous injection of ~700 MBq of 99mTc-DPD (n=877),
99mTc-PYP (n=199) or 99mTc-HMDP (n=141), providing an expected radiation dose of
~5 mSv per patient. Whole body planar images were acquired 3 h post-injection (with the
exception of some 99mTc-PYP images in which thoracic planar images were acquired 1 h
post-injection). Images were acquired using low energy, high-resolution collimators and a
scan speed of 10 cm/min (99mTc-DPD and 99mTc-HMDP) or for a total of 750000 counts
(99mTc-PYP).24
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Cardiac retention of all 99mTc-DPD and 99mTc-HMDP scans was defined by a single
reader at each center according to the grading devised by Perugini et al.21 99mTc-PYP was
scored by a single reader at each center using the following grading system: Grade 0 – absent
cardiac uptake; Grade 1 – mild uptake less than bone; Grade 2 - moderate uptake equal to
bone; Grade 3 - high uptake greater than bone.
Histology, Immunohistochemistry and Proteomic analysis
All formalin fixed paraffin-embedded biopsies were stained with Congo red dye and viewed
under crossed polarized light. Immunohistochemical staining of all amyloid deposits was
performed using monospecific antibodies reactive with serum amyloid A protein (SAA),
kappa and lambda immunoglobulin light chains and transthyretin, as previously described,29
and where necessary, apolipoprotein A-I, and fibrinogen Aα-chain. Where required, Congo
red positive deposits were stained and viewed by immunoelectron microscopy or
microdissected for proteomic analysis, as previously described.30
All biopsy specimens in which amyloid deposits were not detected by Congo red
histology were further examined by light microscopy following staining with hematoxylin
and eosin (H&E) and Masson’s trichrome, and wherever possible, additionally examined by
electron microscopy.
Monoclonal protein studies
Presence of a monoclonal protein was sought by IFE of serum and urine and by serum free
light chain (sFLC) assay (Freelite, The Binding Site)31, 32 in all patients. Presence of a
monoclonal protein was defined as an abnormal FLC ratio (< 0.26 or > 1.65) on serum
Freelite assay, or presence of a band on IFE of serum or urine.
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Genetic testing
All patients with cardiac ATTR amyloid underwent sequencing of the TTR gene. DNA was
extracted from whole blood, amplified by polymerase-chain-reaction assay and the whole
coding region of the transthyretin (TTR) gene was sequenced, as previously described.33
Statistical analyses
Sensitivity and specificity of radionuclide scan findings accompanied by positive and
negative predictive values for the proposed diagnostic criteria (including 95% confidence
intervals) were calculated using IBM SPSS Statistics 22 software.
Results
Patients
A total of 1498 patients were referred for evaluation of suspected cardiac amyloidosis to the
relevant specialist amyloidosis centers. EMBs were performed in a total of 374 patients, 327
with amyloid and 47 without amyloid. Among 1124 remaining patients in whom EMBs were
not performed, 391 cases had cardiac amyloidosis on the basis of a characteristic
echocardiogram +/- CMR from the specialist amyloidosis center and histological proof of
amyloid in extra-cardiac tissue. There were 139 patients with histologically proven extra-
cardiac amyloid without evidence of cardiac involvement by echocardiography +/- CMR.
The remainder (n=360) had no histologic or cardiac imaging evidence of amyloid. Patients
with cardiac imaging (echocardiogram +/- CMR) from the specialist amyloid center that was
characteristic of amyloid but in whom histological proof of amyloid was lacking (n=281)
were excluded from all analyses, due to diagnostic uncertainty. The diagnostic algorithm
detailing selection of patients for analysis is shown in Figure 1. The final diagnoses among
1217 analysable patients (857 with amyloid and 360 without amyloid), established on the
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basis of these investigations, coupled with immunohistochemical and/or proteomic typing of
amyloid and genetic analyses, are shown in Table 1.
Histology
Amyloid was identified histologically in 857 patients from the following tissues; heart
(n=327), fat (n=209), bowel (n=92), bone marrow (n=56), lymph node, including salivary
gland (n=43), bladder (n=29), kidney (n=27), lung (n=20), nerve (n=14) and from 12 other
sites (n=40). Of the 360 patients without amyloid, 47 had EMBs which were negative for
amyloid by Congo red staining.
Radionuclide ‘bone’ scintigraphy with 99mTc-DPD, 99mTc-PYP, or 99mTc-HMDP
Radionuclide scans were validated against Congo red histology of an EMB, which is the
current gold standard for diagnosis of cardiac ATTR amyloid, in 374 patients (261 with
cardiac ATTR amyloid, and 113 without cardiac ATTR amyloid). The results for each of the
three radionuclide tracers are shown in Table 2. These results indicate that the sensitivity of a
positive (grade 1, 2 or 3 cardiac uptake) scan alone for detecting cardiac ATTR amyloid
deposits is >99% (positive radionuclide scan in 259/261 patients) and the specificity of a
positive scan (grade 1, 2 or 3 cardiac uptake) for cardiac ATTR amyloid deposits is 68%
(negative radionuclide scan in 77/113 patients without cardiac ATTR amyloid) (Table 3).
The low specificity of a positive scan for cardiac ATTR amyloid deposits was almost entirely
due to cardiac uptake of tracer among patients with cardiac AL or cardiac AApoAI
amyloidosis. The sensitivity and specificity of grade 2 or 3 cardiac uptake on radionuclide
scan for cardiac ATTR amyloid deposits among the 374 patients in this cohort who
underwent EMB was 91% and 87% respectively (Table 3). A single patient with cardiac
ATTR amyloid deposits detected on EMB had a negative 99mTc-DPD scan (Table 2). Review
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of this individual’s case revealed scanty amyloid deposits on EMB, an interventricular septal
thickness on echocardiography of only 10 mm, modest elevation of cardiac biomarkers (high
sensitivity troponin 14 ng/ml and NT-proBNP 51 pmol/L) and a 6-minute walk test distance
of 607 metres (120% of expected for age). This patient therefore had limited sub-clinical
cardiac ATTR amyloid deposits rather than clinically significant cardiac ATTR amyloidosis.
One patient referred with histologically proven cardiac ATTR amyloid had a negative 99mTc-
PYP scan, but review of a sub-aortic myomectomy biopsy obtained at aortic valve
replacement demonstrated only a single, tiny focus of sub-clinical amyloid. Of the two
patients with no amyloid on EMB but with radionuclide scans that were grade 2 or higher,
one had a Perugini grade 3 99mTc-DPD scan and the other a grade 2 99mTc-PYP scan
(Table 2). Both of these patients had a plasma cell dyscrasia and an echocardiogram that was
characteristic of amyloidosis, leading us to question whether the negative EMBs in both cases
were ‘false’ negatives.
Radionuclide scintigraphy findings in all 1217 patients (including 374 patients who
underwent EMB) corroborated the findings among those who underwent EMB and indicated
that the sensitivity of a positive (grade 1, 2 or 3 cardiac uptake) scan alone for detecting
cardiac ATTR amyloid deposits was >99% (positive scans in 528/530 with cardiac ATTR
amyloid) with a specificity of 86% (negative scans in 591/687 patients without cardiac ATTR
amyloid). The sensitivity of grade 2 or 3 cardiac uptake on a radionuclide scan for cardiac
ATTR amyloid deposits was 90% with a specificity of 97%. The radionuclide scan findings
for all 1217 patients are shown in Supplementary Table 1, and for each of the individual
‘bone’ tracers are shown in Supplementary Tables 2, 3 and 4. Sensitivity and specificity
analyses for the whole cohort of 1217 patients are shown by individual tracer in
Supplementary Tables 5, 6 and 7.
12
Monoclonal Protein studies
Among 237 with systemic AL amyloidosis in this cohort, 235 (99%) had evidence of a
monoclonal protein by one or more of serum IFE, urine IFE and sFLC assay. Interestingly,
among 562 patients from the cohort with ATTR amyloid, whose median age was 75 years,
107 (19%) cases had a detectable monoclonal protein using these very sensitive techniques.
The monoclonal protein findings presented here were corroborated by analysis of two
separate, larger cohorts of patients with histologically proven systemic AL amyloidosis.
Among 714 patients with systemic AL amyloidosis from the UK National Amyloidosis
Centre, 98.9% had evidence of a monoclonal protein, and among 1465 patients from a
collaborative project between The Amyloidosis Research and Treatment Center, Pavia, Italy
and the Mayo Clinic, USA, 99.8% had a detectable monoclonal protein (data not shown).
Combined Radionuclide Scintigraphy and Monoclonal Protein findings
The combined finding of grade 2 or 3 cardiac uptake on radionuclide scintigraphy and the
absence of a monoclonal protein by IFE of serum and urine and by serum FLC measurement,
was 100% specific for presence of cardiac ATTR amyloid both in the subgroup of 374
patients who underwent EMB and in the whole cohort of 1217 patients (positive predictive
value 100% (CI 98.0-100%)). Detailed sensitivity and specificity analyses are shown in
Table 4.
Genotyping
Among 562 patients with ATTR amyloid (530 with cardiac involvement), all had their TTR
gene sequenced. This was wild-type sequence in 304 cases. Thirty-five different pathogenic
variants were identified among the remaining 258 patients.
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Radionuclide scan results by individual amyloidogenic TTR variant are shown in
Supplementary Table 8. These results indicate that radionuclide scan findings were
consistent with that expected according to the clinical and echocardiographic findings as well
as the known likelihood of cardiac involvement associated with individual TTR variants. For
example, younger patients with V30M-associated ATTR amyloidosis have a predominant
neuropathic phenotype without cardiac amyloidosis while older patients with V30M-
associated amyloidosis can present with cardiac amyloidosis. The radionuclide scintigraphy
findings among 48 patients with V30M-associated ATTR amyloidosis showed no cardiac
uptake in 23 cases (median age 37 years, median interventricular wall thickness on
echocardiography 10 mm), and grade 1, 2 and 3 uptake in 6, 18, and 1 patient respectively
(median age 68 years, median interventricular wall thickness on echocardiography 15 mm
among those with positive radionuclide scans). There did not appear to be any particular
mutation in which there was a discrepancy between the clinical picture and radionuclide scan
findings.
Discussion
The diagnosis of cardiac amyloidosis is often delayed or missed due to the poor sensitivity
and specificity of echocardiography,10 coupled with the current requirement for histologic
confirmation of amyloid in a tissue biopsy. The diagnosis of wild-type cardiac ATTR
amyloidosis is particularly challenging due both to it presenting in older age34 (when
confounding co-morbidities such as coronary heart disease, hypertension and aortic stenosis
frequently co-exist), and to the absence of any specific extra-cardiac features or supportive
biomarkers in the blood. This contrasts with variant ATTR amyloidosis and AL amyloidosis
which are supported by the presence of a TTR gene mutation33 or monoclonal
immunoglobulin respectively.31, 32 Currently, wild-type ATTR amyloidosis is mostly
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diagnosed in men over 70 years and in fewer than three per million per year,35 which
contrasts hugely with the high frequency of ATTR amyloid deposits found at autopsy and the
high prevalence in common syndromes such as HFpEF.28 Despite the lack of a blood marker
and the fact that myocardial biopsy is required for a definitive diagnosis, recent data from
specialist amyloid centres suggest that wild-type ATTR amyloidosis is now diagnosed more
frequently than variant ATTR amyloidosis.7
Our analyses of 374 patients with EMBs, corroborated in the whole cohort of 1217
patients, indicate that cardiac uptake (grade 1, 2 or 3) on a radionuclide ‘bone’ scan is >99%
sensitive but not completely specific for cardiac ATTR amyloid (68% specificity compared to
EMB histology), the low specificity resulting largely from low grade uptake in patients with
cardiac AL or cardiac AApoAI amyloidosis.36 The specificity for cardiac ATTR amyloid of
grade 2 or 3 cardiac uptake on radionuclide imaging increases to ~87%, whilst the sensitivity
falls to 91%. Since it is absolutely essential to avoid misdiagnosis of cardiac ATTR
amyloidosis in a patient who actually has cardiac AL amyloidosis requiring chemotherapy,
the primary aim of the proposed diagnostic criteria was to achieve very high diagnostic
specificity. The specificity and positive predictive value for cardiac ATTR amyloid of the
combination of grade 2 or 3 cardiac uptake on a radionuclide scan, and absence of a
detectable monoclonal protein despite serum IFE, urine IFE and sFLC assay was 100% (PPV
CI 99.0-100%) in this cohort of 1217 patients and was also 100% among each of the 3
different radiotracer cohorts. Although the authors acknowledge that further validation of
99mTc-HMDP scintigraphy against EMB histology is required, the presented preliminary data
for 99mTc-HMDP, indicate that it behaves identically to 99mTc-DPD and 99mTc-PYP. The data
clearly indicate that the combination of grade 2 or 3 cardiac uptake on a radionuclide ‘bone’
scan, and absence of a detectable monoclonal protein by serum IFE, urine IFE and sFLC
(Freelite) assay is diagnostic of cardiac ATTR amyloid.
15
In a patient with symptoms of heart failure and an echocardiogram or CMR
suggesting the possibility of amyloidosis, the combined findings listed above establish the
diagnosis of cardiac ATTR amyloidosis without a requirement for positive Congo red
histology. Patients with cardiac uptake on a radionuclide scan who have a monoclonal
protein require additional diagnostic testing, including histologic or proteomic typing of
amyloid. A diagnostic algorithm for cardiac amyloidosis based on the findings presented
here is shown in Figure 2. A diagnosis of cardiac ATTR amyloidosis should be followed by
TTR genotyping in all cases in order to differentiate between wild-type and variant ATTR
cardiac amyloidosis. In patients with a family history of cardiac amyloidosis and wild-type
TTR gene sequence, the authors would suggest additional sequencing of the apoAI gene to
exclude the remote possibility of cardiac AApoAI amyloidosis.
It is noteworthy that 11 patients in the whole cohort of 1217 had low grade (1 or 2)
cardiac uptake on radionuclide scintigraphy despite ‘so called’ absence of cardiac
amyloidosis (i.e., ‘false positive’ scans). The majority did not undergo EMB and all but one
with a known TTR mutation had undefined cardiomyopathies; it is thus likely that they did
indeed have minor cardiac ATTR amyloid deposits without echocardiographic or CMR
evidence of cardiac ATTR amyloidosis.
Importantly, the findings and recommendations documented here do not eliminate the
need for histological demonstration and typing of amyloid among patients with cardiac
amyloidosis generally. On the contrary, a monoclonal protein was detected in a surprisingly
high proportion (19%) of patients with ATTR amyloidosis in this cohort (likely, at least in
part, due to referral bias), and the sensitivity and specificity of grade 2 or 3 cardiac uptake on
radionuclide scan for diagnosing cardiac ATTR amyloidosis as opposed to cardiac AL
amyloidosis in patients who had a monoclonal protein were 92% and 91% respectively,
highlighting the need for histological typing of amyloid by immunohistochemical staining
16
and/or proteomic analysis, often from an EMB, in any patient who does not fulfil the
diagnostic criteria for cardiac ATTR amyloidosis proposed above.
It should be noted that the patients presented here were not unselected, but rather
referred to specialist amyloid centers for evaluation of suspected amyloidosis. Further study
is required to validate these findings within the general ‘unselected’ cardiology population.
In summary, cardiac ATTR amyloidosis can be reliably diagnosed in the absence of
histology provided that all of the following criteria are met;
Heart failure with an echocardiogram or CMR that is consistent with or suggestive of
amyloidosis
Grade 2 or 3 cardiac uptake on a radionuclide scan, using either 99mTc-DPD, 99mTc-
PYP or 99mTc-HMDP
Absence of a detectable monoclonal protein despite serum and urine IFE, and sFLC
(Freelite) assay
Histological confirmation and typing of amyloid should be sought in all cases of suspected
cardiac amyloidosis in which these criteria are not met.
17
Acknowledgements
We thank our many physician colleagues for referring and caring for the patients. We thank
J Berkeley for expert preparation of the manuscript.
Funding sources
This work was funded in the UK by the Department of Health; in Italy by grants from the
‘Associazione Italiana per la Ricerca sul Cancro’ Special Program Molecular Clinical
Oncology 5 per mille n. 9965 and the Cariplo Foundation (n 2013-0964); in the US, by
research funding from the Predolin Foundation, the JABBS Foundation, the Robert A Kyle
Hematologic Malignancies Fund, Pfizer Inc., Alnylam Pharmaceuticals Inc., ISIS
Pharmaceuticals and Prothena Inc.
Disclosures
Dr Maurer serves on advisory boards and DSMBs from Pfizer Inc., Alnylam Pharmaceuticals
Inc., ISIS Pharmaceuticals and Prothena Inc. Dr Dorbala is a stock holder in General
Electric. Dr Rapezzi has received unrestricted educational grant support from Pfizer Inc.,
including one for the project “Early identification of mutant and wild-type ATTR-related
cardiac amyloidosis” and honoraria from Novartis, Servier and Abbott. Dr Merlini receives
honoraria from Pfizer Inc. Dr Castano receives funding from ACC/Merck Fellowship in
Cardiovascular disease. Dr Dispenzieri’s institution receives research funding from Pfizer
Inc., Alnylam Pharmaceuticals Inc., Takeda Pharmaceuticals, Celgene, and Janssen
Pharmaceutica. Dr Hazenberg serves on the advisory board of Pfizer Inc., and a DSMB of
GSK. Dr Johnson serves on an advisory board for Pfizer Inc.
18
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Figure Legends
Figure 1. Selection of patients for analysis. Among 1217 ‘evaluable’ patients, 374
underwent endomyocardial biopsy and 843 were diagnosed with presence and type or
absence of amyloid on the basis of extra-cardiac histology coupled with echocardiography +/-
cardiac magnetic resonance imaging (CMR). Patients in whom there was diagnostic
uncertainty were excluded from all analyses (n=281).
Figure 2. Diagnostic algorithm for patients with suspected amyloid cardiomyopathy.
Echocardiographic features suggesting/indicating cardiac amyloid include (but are not limited
to) increased LV wall thickness, restrictive filling pattern, abnormal left and right ventricular
longitudinal strain and atrial septal thickening. Features suggesting/indicating cardiac
amyloid on CMR include (but are not limited to) restrictive morphology, abnormal
gadolinium kinetics and extracellular volume expansion based on T1 mapping.
24
Table 1. Final diagnoses in patients with and without endomyocardial biopsy (EMB)
Patients EMB N=374 (31%)
No EMB† N=843 (69%)
All N=1217 (100%)
Cardiac transthyretin (ATTR) amyloid 261 269 530 Cardiac AL amyloidosis 62 119 181 Cardiac Apolipoprotein A-I amyloidosis 2 3 5 Cardiac amyloidosis of unknown type 2 0 2 No cardiac amyloid Amyloidosis without cardiac amyloid infiltration Systemic AL amyloidosis, no cardiac involvement Transthyretin amyloidosis, no cardiac involvement AA amyloidosis, no cardiac involvement ApoAI amyloidosis, no cardiac involvement Fibrinogen A α-chain amyloidosis, no cardiac involvement Gelsolin amyloidosis, no cardiac involvement Lysozyme amyloidosis, no cardiac involvement Amyloidosis of unknown fibril type, no cardiac involvement Localised AL amyloidosis, no cardiac involvement No amyloidosis Hypertrophic CM (HCM) Heart failure with preserved ejection fraction (HFPEF) Hypertensive heart disease Anderson-Fabry disease Undetermined cardiomyopathy TTR mutation carriers Light chain deposition disease
47 0 0 0 0 0 0 0 0 0 0 47 1 8 0 0 32 5 1
452 139 56 32 3 2 3 1 1 2 39 313 41 52 8 2 182 28 0
499 139 56 32 3 2 3 1 1 2 39 360 42 60 8 2 214 33 1
†Presence/absence of cardiac amyloidosis determined on the basis of echocardiography within specialist centers +/- CMR
25
Table 2. Radionuclide ‘bone’ scintigraphy findings among 374 patients with endomyocardial biopsies
End
om
yocard
ial bio
psy fin
din
gs
99mTc-DPD scan findings
Perugini 0 Perugini 1 Perugini 2 Perugini 3 N
No cardiac amyloid 31 3 0 1 35
Cardiac transthyretin amyloid deposits 1 8 130 23 162
Cardiac AL amyloid deposits 21 13 7 2 43
Cardiac apoAI amyloid deposits 0 2 0 0 2
Cardiac amyloid deposits of unknown type 1 1 0 0 2
Total N 54 27 137 26 244
99mTc-PYP scan findings
Grade 0 Grade 1 Grade 2 Grade 3
No cardiac amyloid 7 1 1 0 9
Cardiac transthyretin amyloid 1 10 7 67 85
Cardiac AL amyloid deposits 10 1 3 1 15
Cardiac apoAI amyloid deposits 0 0 0 0 0
Cardiac amyloid deposits of unknown type 0 0 0 0 0
Total N 18 12 11 68 109
99mTc-HMDP scan findings
Grade 0 Grade 1 Grade 2 Grade 3
No cardiac amyloid 3 0 0 0 3
Cardiac transthyretin amyloid deposits 0 3 4 7 14
Cardiac AL amyloid deposits 4 0 0 0 4
Cardiac apoAI amyloid deposits 0 0 0 0 0
Cardiac amyloid deposits of unknown type 0 0 0 0 0
Total N 7 3 4 7 21
26
Table 3. Sensitivity and specificity of radionuclide ‘bone’ scintigraphy vs EMB histology
Positive radionuclide scan vs cardiac amyloid deposits (N=374)
Positive scan (Grade 1, 2, or 3) Negative scan (Grade 0) Sensitivity and specificity (CI)
Cardiac amyloid deposits 289 38 88% (84-92%) sensitive†
No cardiac amyloid deposits 6 41 87% (73-95%) specific
Positive radionuclide scan vs cardiac ATTR amyloid deposits (N=374)
Positive scan (Grade 1, 2, or 3) Negative scan (Grade 0)
Cardiac ATTR amyloid deposits 259 2 >99% (97-100%) sensitive
No cardiac ATTR amyloid deposits 36 77 68% (59-77%) specific
Grade 2 or 3 radionuclide scan vs cardiac ATTR amyloid deposits (N=374)
Grade 2/3 scan Grade 0/1 scan
Cardiac ATTR amyloid deposits 238 23 91% (87-94%) sensitive
No cardiac ATTR amyloid deposits 15 98 87% (79-92%) specific
†The sensitivity of a positive radionuclide scan for detecting cardiac amyloid deposits of any type is likely to be falsely high due to the high
proportion of patients with ATTR amyloid in the sample.
27
Table 4. Combined radionuclide ‘bone’ scintigraphy and monoclonal protein studies
Grade 2 or 3 radionuclide scan + absence of clone vs ATTR amyloid deposits on EMB (N=374)
Grade 2/3 scan + no clone Grade 0/1 scan OR clone Sensitivity and specificity (CI) Positive (PPV) and Negative predictive (NPV)values (CI)
Cardiac ATTR amyloid deposits
182 79 70% (64-75%) sensitive NPV 59% (52-66%)
No cardiac ATTR amyloid deposits
0 113 100% (96-100%) specific PPV 100% (98-100%)
Grade 2 or 3 radionuclide scan + absence of clone vs ATTR amyloid deposits on histology from any organ (N=1217)
Grade 2/3 scan + no clone Grade 0/1 scan OR clone
Cardiac ATTR amyloid
391 139 74% (70-77%) sensitive† NPV 83% (80-86%)
No cardiac ATTR amyloid
0 687 100% (99-100%) specific PPV 100% (99-100%)
†The low sensitivity was due to the exclusion of patients with cardiac ATTR amyloid exhibiting a monoclonal protein (88 of 530 patients with
cardiac ATTR amyloid), and grade 0 or 1 radionuclide scans among a further 51 patients with cardiac ATTR amyloid.